JP2003066894A - Plasma display device and driving method thereof - Google Patents

Abstract

(57) [Summary] [PROBLEMS] To provide a high-quality plasma display device having high luminance and capable of suppressing a false contour of a moving image. SOLUTION: The plasma display device writes and holds multi-gradation data consisting of a plurality of weighted bits B7, B6,..., B0, so that one field Tf corresponding to a plurality of bits is converted into a plurality of subfields T7, T6. ,..., T0, each bit is written in a corresponding subfield, and a drive signal of a pulse number corresponding to the weight of the bit is applied to the sustain electrode to hold the bit. At this time, the pulse interval of the drive signal is adjusted in each subfield, and a uniform time width is assigned to each subfield in one field. Further, the pulse interval of the driving signal is compressed and adjusted in each subfield, and all subfields T7, T6,.
It is preferable to compress and assign 0 to suppress the false contour of the moving image.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a plasma display device and a driving method thereof. More specifically, it relates to an improved technique of the subfield method for the purpose of gradation display.

[0002]

2. Description of the Related Art Various flat panel type display devices have been developed as an image display device which replaces the currently mainstream cathode ray tube (CRT). As a flat panel type display device, a liquid crystal display device (LCD), an electroluminescence display device (ELD), and a plasma display device (PDP) are known. Among them, the plasma display device has advantages such as relatively large screen and wide viewing angle, excellent resistance to environmental factors such as temperature, magnetism and vibration, and long life. , Is expected to be applied to large-scale information terminal devices for public use as well as wall-mounted TVs for home use.

In a plasma display device, a voltage is applied to a discharge cell in which a discharge gas such as an inert gas is sealed in a discharge space, and vacuum ultraviolet rays generated by glow discharge in the discharge gas cause fluorescence in the discharge cell. It is a display device that emits light by exciting a body layer. That is, each discharge cell is driven by a principle similar to that of a fluorescent lamp, and a large number of discharge cells are collected as pixels to form one display screen. Basically, each discharge cell is driven on / off between lighting and extinguishing, and in principle, two-gradation display is performed. Plasma display devices are roughly classified into a DC drive type (DC type) and an AC drive type (AC type) according to a method of applying a voltage to a discharge cell. The AC type plasma display device is suitable for high definition because it is sufficient to form the barrier ribs that partition the individual discharge cells in the display screen in stripes. Further, since the surface of the electrode for discharging is covered with the dielectric layer, the electrode has advantages that it is hard to wear and has a long life.

[0004]

Basically, a subfield method is known in order to realize multi-gradation display in a plasma display device in which individual discharge cells are turned on / off to display a screen. . According to this method, one field is divided into a plurality of sub-fields corresponding to a plurality of bits because the weighted multi-tone data consisting of a plurality of bits is written and held in a pixel. Then, each bit is written in the corresponding subfield and a drive signal corresponding to the weighting of the bit is applied to the discharge cell to hold the bit. In other words, in this sub-field method, the display period of one field is divided into N sub-fields so that the display period is divided into N sub-fields in order to emit light the number of times corresponding to the weighting of each bit digit of N-bit pixel data. . For example, when the pixel data is 8 bits, the display period of one field is divided into eight subfields. At this time, the number of discharge light emission in each subfield is set to, for example, 1 time, 2 times, 4 times, 8 times, 16 times ... 128 times in order, and 256 gradations are obtained by combining these 8 subfields. Is displayed.

The number of times of discharge light emission corresponds to the number of pulses included in the drive signal. Conventionally, the pulse frequency of the drive signal applied to each subfield has been constant. In other words, the time intervals of the pulses are constant. Therefore, the subfield corresponding to the upper bits has a large number of times of light emission, and thus the subfield period is inevitably long. In contrast,
Since the number of times of light emission is small in the subfield corresponding to the lower bit, the time width of the subfield is small. In this way, conventionally, the emission width is modulated by adjusting the time width of each subfield. In this method, all subfields are set to fit within one field in order to maintain the brightness of the screen. By doing so, the time width of the subfield becomes smaller as the bit becomes lower. Particularly, in the least significant bit, the effective time width included in the subfield period becomes extremely short, and there is a problem that it is difficult to perform stable display.

Further, the subfield method has a problem that when a moving image is displayed on a television screen, the contour of the picture pattern is disturbed and a pseudo contour other than the actual contour appears, thereby disturbing the image quality. In this specification, a pseudo contour that appears when a moving image is displayed is called a moving image pseudo contour. Conventionally, a method called a time compression method has been used in order to suppress a moving image pseudo contour. This time compression method is a method of shortening the time width of each subfield and compressing and assigning all the subfields to a part of the time width of one field. For example, it is desirable to shorten the total time of the sub-fields and suppress it to about 1/2 or 1/3 in one field. However, if the pulse frequency of the drive signal is uniformly increased to shorten the subfield, the least significant bit (LS
The subfield time corresponding to B) becomes shorter,
If the above-mentioned time width is set to 1/2 or 1/3, the stability of discharge will be disturbed.

[0007]

SUMMARY OF THE INVENTION It is an object of the present invention to solve the problems of the subfield method described above and to provide a high quality plasma display device which has high brightness and is capable of suppressing moving picture pseudo contours. . The following measures have been taken to achieve this purpose. That is, a dischargeable gas is sealed between a pair of substrates joined to each other, one substrate is provided with first and second electrodes corresponding to each scanning line, and the other substrate is provided with the electrodes. Is a panel in which a third electrode is formed corresponding to each data line, and drives the first, second and third electrodes to sequentially write data in the intersections of each scanning line and each data line. And hold it,
In a plasma display device including a drive unit for displaying an image for one field, the drive unit writes and holds multi-gradation data consisting of a plurality of weighted bits,
One field is divided into a plurality of subfields corresponding to a plurality of bits, each bit is written in a corresponding subfield, and a driving signal having a pulse number corresponding to the weighting of the bit is applied to the first and second electrodes. Hold the relevant bit, and further adjust the pulse interval of the drive signal in each subfield to shorten the pulse interval in the subfield with a large number of pulses and lengthen the pulse interval in the subfield with a small number of pulses. Characterize. Preferably, the driving unit adjusts a pulse interval of the driving signal in each subfield, and thus allocates a uniform time width to each subfield in one field. Further, the drive unit may compress and adjust the pulse interval of the drive signal in each subfield, and thus compress and allocate all the subfields to a part of the time width of one field.

According to the present invention, the pulse frequency (pulse interval) is variably set in each subfield, instead of making the pulse frequency of the drive signal constant in each subfield as in the conventional case. Specifically, the pulse interval is shortened in the subfield corresponding to the upper bits of the multi-gradation data, while the pulse interval is lengthened in the subfield corresponding to the lower bits. By doing so, it is possible to equalize the time widths assigned to the subfields within one field, and it is possible to secure sufficient time even for the subfields corresponding to LSB. Thereby, the discharge can be stabilized. Further, since a sufficient time width can be secured even in the LSB side subfield, it is possible to apply time compression to 1/2 or 1/3 over all the subfields, and it is possible to suppress a moving image pseudo contour.

[0009]

BEST MODE FOR CARRYING OUT THE INVENTION Embodiments of the present invention will be described in detail below with reference to the drawings. FIG. 1 is a schematic exploded perspective view showing the basic configuration of a plasma display device according to the present invention. This plasma display device is an AC type and belongs to a so-called three-electrode type. As shown in the figure, the present plasma display device comprises a front panel 10 and a rear panel 20 joined together at their outer peripheral portions. The light emission of the phosphor layer 25 on the rear panel 20 is observed through the front panel 10.

The front panel 10 is provided with a transparent glass substrate 11 and stripes on the glass substrate 11.
A plurality of pairs of scan electrodes Y and sustain electrodes X made of a transparent conductive material, and a dielectric layer 14 made of a dielectric material formed on the glass substrate 11 so as to cover these electrodes.
And a protective film 15 made of MgO or the like formed on the dielectric layer 14. A bus electrode made of a metal material having a low electric resistivity is formed on the scan electrode Y made of a transparent conductive material in order to reduce its impedance. Similarly, a bus electrode made of a narrow metal material is formed on the sustain electrode X made of a transparent conductive material. The gap size between the scan electrode Y and the sustain electrode X is 10 to 100 μm. The array pitch of the pair of scan electrodes Y and sustain electrodes X is 600 to 1200 μm.

On the other hand, the rear panel 20 has a glass substrate 21.
A plurality of data electrodes H arranged in stripes on the dielectric material layer 23 formed on the glass substrate 21 including the data electrodes H, and the adjacent data electrodes H on the dielectric material layer 23. Insulating barrier ribs 24 extending in parallel with the data electrodes H in a region between the barrier ribs and the barrier ribs 24 from above the dielectric material layer 23.
And a phosphor layer 25 provided over the side wall surface of the. The phosphor layer 25 is a red phosphor layer 25R when performing color display in an AC plasma display device.
It is composed of a green phosphor layer 25G and a blue phosphor layer 25B, and the phosphor layers 25R, 25G, 2 of the respective colors are formed.
5B are provided in a predetermined order. FIG. 1 is an exploded perspective view, and the top of the partition wall 24 on the rear panel 20 side actually contacts the protective film 15 on the front panel 10 side. A pair of scan electrodes Y and sustain electrodes X and two partitions 24
The region where the data electrode H located between the two overlaps corresponds to the discharge cell. A discharge gas, such as an ionizable rare gas, is enclosed in the discharge space surrounded by the adjacent partition walls 24, the phosphor layer 25, and the protective film 15. The front panel 10 and the rear panel 20 are joined at their outer peripheral portions using frit glass. The height of the partition wall 24 is 50 to 200 μm.
Further, the width dimension of the groove sandwiched between the adjacent partition walls 24 is 100 to
It is 400 μm.

The row direction in which the projected images of the scan electrodes Y and the sustain electrodes X extend and the column direction in which the projected images of the data electrodes H extend are orthogonal to each other, and the pair of scan electrodes Y and sustain electrodes X emit light of the three primary colors. A region orthogonal to one set of the phosphor layers 25R, 25G, 25B corresponds to one pixel. Since a glow discharge is generated between the pair of scan electrodes Y and sustain electrodes X, this type of AC plasma display device is called "surface discharge type".

This surface discharge type plasma display device has a three-electrode structure in which a dischargeable gas is sealed between a pair of substrates 11 and 21 bonded to each other as described above, and electrodes are formed on each substrate. Has become. That is, the first and second substrates 11 corresponding to the scanning lines extending in the row direction are formed on one substrate 11.
The scan electrodes Y and the sustain electrodes X, which are the electrodes, are formed, and the data electrodes H, which are the third electrodes, are formed on the other substrate 21 corresponding to the data lines extending in the column direction. Dots are formed at the intersections of each scanning line and each data line, and three dots of RGB form one pixel.

Usually, between the pair of glass substrates 11 and 21,
The gas filled in the formed discharge space is neon and
Xenon gas is an example of an inert gas such as lithium or argon
For example, it is composed of a mixed gas of about 4%. example
For example, the total pressure of the mixed gas is 6 × 10. ^FourPa ~ 7 x 10^FourPa
And the partial pressure of xenon is 3 × 10³It is about Pa.

FIG. 2 schematically shows a three-electrode structure of the plasma display device shown in FIG. The n scanning electrodes Y1 to Yn are formed corresponding to the scanning lines along the row direction (horizontal direction). Here, n represents the number of scanning lines. The sustain electrodes X1 to Xn are formed in parallel with the scan electrodes Y1 to Yn. On the other hand, m data electrodes H1 to Hm are formed along the data lines in the column direction (vertical direction). Here, m represents the number of data lines. A dot D is formed at each intersection of the m data lines and the n scan lines. A plasma discharge is excited by applying a drive signal to the scan electrode Y, the sustain electrode X, and the data electrode H in accordance with a predetermined sequence, and the ultraviolet rays generated thereby are irradiated to the phosphor to emit light, thereby displaying an image. It will be possible.

FIG. 3 is a timing chart schematically showing a driving method of the three-electrode type plasma display device shown in FIG. This timing chart shows a drive waveform focusing on the dot D located in the i-th column and the j-th row.
A drive circuit (not shown) connected to the panel shown in FIG.
Applies the first drive signal to the scan electrode Yj,
The second drive signal is applied to j and the third drive signal is applied to the data electrode Hi. In the example of FIG. 3, one field period Tf
This is a case where two gradation display is performed by using all of

The field period Tf is a reset period Tr,
It is divided into an address period Ta and a holding period Tsus. First, in the reset period Tr, before writing data to each dot, the charge inside the panel is discharged to reset the entire screen to a uniform state. Alternatively, it may be reset to a uniform state by charging the charges inside the panel. For this purpose, a drive signal is applied between all scan electrodes Y and sustain electrodes X in the reset period Tr. The scan electrodes Y are electrically separated one by one, while the sustain electrodes X are all commonly connected. Subsequently, in the address period Ta, all scanning lines are line-sequentially scanned to select one line at a time. In order to select the j-th scanning line, the pulse-shaped first drive signal is applied to the scanning electrode Yj. The period during which one scan line is selected is set to Tsel
And is equal to the pulse width of the first drive signal. At this time, the third drive signal is sent to the data electrode H side in synchronization with the line-sequential scanning of the scan lines. For example, when writing 1 data to the dot in the j-th row and the i-th column, the illustrated third drive signal is applied as a pulse to the data electrode Hi. Conversely, no pulse is applied when writing 0 data to the dot in the j-th row and the i-th column. In this way, the address period Ta is a period for addressing and selecting the scanning lines, and the selection is repeated for the number of scanning lines of the display, and in accordance therewith, the third drive signal corresponding to the binary information 0 and 1 of the image is generated. It is applied to the data electrode H. The address period Ta = Tsel × n. Corresponding to the dot Dji to be displayed, ON to the data electrode Hi
= 1 or OFF = 0 drive signal is applied to scan electrode Yj
As for, the first drive signal is applied according to the position of the dot Dji. After the line-sequential scanning for one screen is completed in the vertical direction (vertical direction), the holding period (sustain period) Tsu
Enter s.

In the sustain period Tsus, the light emitting / non-light emitting operation is performed according to the ON / OFF state written in the address period Ta. ON = 1 in the address period Ta
When is written, light emission is maintained to obtain a desired brightness. On the contrary, when OFF = 0 is written in the address period, the non-light emitting state is maintained. In addition, the sustain period Tsu
At s, a pulsed drive signal is applied between the scan electrode Y and the sustain electrode X, and light emission is repeated according to the pulse. As described above, the plasma display device basically turns dots on and off.
It is driven and two-gradation display is performed.

Next, with reference to FIG. 4, a driving method for performing multi-gradation display in the plasma display device will be described. Figure 4
Before describing the driving method of the present invention, shows a multi-gradation display by a conventional general subfield method as a reference. In the case of a two-gradation display, the data written in each dot has a 1-bit structure of 01. On the other hand, in the case of multi-gradation display, multi-bit data consisting of a plurality of bits weighted in order from the upper digit to the lower digit is written in each dot. In the subfield method, one field period Tf is divided into a plurality of subfields corresponding to a plurality of bits. In the illustrated example, the multi-gradation data is 8 gradation data from the most significant bit B7 to the least significant bit B0, and the field period Tf is divided into eight subfield periods T7, T6, T5, ... T0. ing.
Here, each bit is written in the corresponding subfield, and a drive signal having a pulse number corresponding to the weighting of the bit is applied between the scan electrode and the sustain electrode during the holding period to hold the bit. In the illustrated example, the most significant bit B7
Is written and maintained in the subfield period T7, the next bit B6 is written in the next subfield period T6,
The least significant bit B0 is sequentially written in the field period Tf.

In each subfield, the drive sequence shown in FIG. 3 is performed to write the corresponding bit. For example, focusing on the first subfield T7,
The screen is collectively reset in the reset period Tr, the most significant bit B7 is written in the address period Ta, and the bit data B7 written in the sustain period Tsus is maintained. B
The dot in which 7 = 1 is written repeats pulse emission, and the dot in which B7 = 0 is written remains non-emissive. Similarly, the subfield driving sequence is repeated in each period T6, T5, ..., T0. In each subfield period T, a period Tr + that does not contribute to the actual brightness
The time length of Ta is the same, but the effective period Tsus that contributes to the brightness is different. That is, drive signals of the number of pulses according to the weighting of bits are applied to each subfield. The most significant bit is applied with the largest number of pulses, the next bit B6 is applied with half the number of pulses, and the number of pulses is halved in the following order. Conventionally, a drive signal having a constant pulse frequency in all subfield periods has been applied between the scan electrodes and the sustain electrodes. Therefore, the sustain period Tsus has a time length simply according to the weighting of the corresponding bit. Therefore, the subfield period T in which Tr, Ta, and Tsus are summed becomes shorter from the most significant bit to the least significant bit, such as T7 to T0.

In the example shown in FIG. 4, the actual field period Tf
On the other hand, if the gradation number is, for example, 256 gradations of 8 bits,
The drive sequence shown in FIG. 3 is repeated as a subfield eight times within the field period Tf, and light emission is performed during the weighted sustain period Tsus. The emission luminance per pulse is constant, but by extending the time length of the sustain period according to weighting in each subfield, the effect is visually integrated over one field period Tf, and the brightness gradation is obtained. Can be recognized as Such a method is called a subfield method.

The problem of the general subfield method shown in FIG. 4 will be briefly described. To simplify the explanation,
It is assumed that one subfield includes only the reset period Tr, the address period Ta, and the sustain period Tsus. The reset period Tr is common to all the subfields and is, for example, 0.4 msec. The address period Ta is also common to all subfields,
For example, it is 1.2 msec. This numerical value corresponds to the VGA standard, and when the number of scanning lines n = 480 and the selection period Tsel of one scanning line is 2.5 μsec, 2.5 μsec × 480 = 1.2 msec is given. Here, assuming that the multi-gradation data has an 8-bit structure, one field period Tf is divided into eight subfield periods T7 to T0. Here, according to the normal NTSC standard, one field period Tf is 16.6 msec. In this case, the sustain period Tsus of the subfield corresponding to the least significant bit is about 0.0149 msec. Therefore, the subfield period T0 corresponding to the least significant bit B0 is reset period 0.4 msec, address period 1.2 msec, and sustain period Tsus0.
The total of 0149 msec is 1.614 msec. When calculated in the same manner, the time length of the subfield period T1 corresponding to the bit B1 is 1.68 msec, and the subfield period T7 corresponding to the most significant bit B7 is 3.
It will be 56 msec. As described above, the weighting of each bit is performed by the length of the sustain period Tsus. In the subfield method, the number of subfields increases as the number of gradations increases. Further, increasing the number of scanning lines n means extending the address period Ta.
As a result, when the number of gradations is increased or the number of scanning lines is increased to improve the image quality, the ratio of the total period of each sustain period Tsus to the actual field period Tf is decreased, which deteriorates the brightness. This is an obstacle to high image quality.

FIG. 5 is a schematic timing chart showing the driving method of the plasma display device according to the present invention. In order to facilitate understanding, parts corresponding to those in FIG. 4 are designated by corresponding reference numerals. . The plasma display device basically has a display characteristic that the brightness changes according to the number of pulses applied during the sustain period. Focusing on this point, in the present invention, the brightness modulation is performed not by the time width modulation but by the number of pulses. The time width control according to the weighting of the sustain period Tsus is not necessarily required as in the conventional example shown in FIG. 4, and each subfield period T7, T6, ..., T0 is set as shown in the timing chart of FIG. The sustain period T that is constant and directly contributes to the luminance in the sustain period T
The period of sus is the same, but each sustain period Ts
The number of pulses corresponding to the weighting of bits is assigned to us. In other words, the pulse frequency is variable in each subfield.

In the example of FIG. 5, assuming that the sustain period Tsus is equally spaced in the field period Tf, the time length of Tsus is B5 as compared with the case of the time width control shown in FIG.
Corresponds to the length of time allocated to. On the other hand, each Ts
The number of pulses applied to us corresponds to the weighting of gradation, and assuming that the pulse frequency of the least significant bit B0 is f1, the frequency at B1 is f2 = 2 × f1, and at B4 f4 = 4 × f1, F128 for upper bit B7
It is sufficient to apply a drive signal having a pulse frequency of = 128 × f1. However, this is a case where the number of pulses per unit time and the luminance are linear to each other, but this is not a problem because it may be non-linear as long as it matches the light emission characteristics. In this new method, the least significant bit LSB
Even in the subfield corresponding to, the sustain period Tsu
Since the length of s is equivalent to the case of the upper bits, it is possible to adopt the time compression method and squeeze the total period of subfields into a part of one field period. Even if the time compression method is used, the sustain period Ts corresponding to the least significant bit
Since the us can be sufficiently secured, it is possible to eliminate the instability of the display operation.

As described above, according to the present invention, the driving unit of the plasma display device adjusts the pulse interval of the drive signal in each subfield to shorten the pulse interval in the subfield in which the number of pulses is large and to decrease the number of pulses. The pulse interval is set longer in the subfield. For example, the driving circuit of the plasma display panel adjusts the pulse interval of the driving signal in each subfield so that an equal time width is assigned to each subfield in one field. In addition, the drive circuit
It is also possible to compress and adjust the pulse interval of the drive signal in each sub-field and thereby compress all the sub-fields in a part of the time width of one field to suppress the allocation moving image pseudo contour.

Here, a mechanism of generating a moving image pseudo contour in the plasma display device will be briefly described. The pseudo contour of the moving image is generated in principle when the sub-field method is adopted for displaying the gradation, and the emission of the weighted time width of each bit is dispersed in the field. to cause. When observing a pixel with a certain gradation, if the pixel remains in the eyes of the observer within one field period, the correct luminance signal corresponding to the gradation data is perceived by the visual integration function. can do. However, when observing the video, the line of sight moves,
If the gradation of the image you are looking at differs from the gradation after moving, the correct subfield emission that constitutes the gradation will not come into your eyes, and the incorrect subfield emission will enter, resulting in a floor failure. It is perceived as light different from the key data. This phenomenon is called moving image pseudo contour. Even if the line of sight does not move, when the signal is switched in the field and reflected in the signal of the subfield, a pseudo contour appears again.

With reference to FIG. 6, the lengths of fields and subfields and the appearance of pseudo contours will be specifically described. As an example, in the case of 8-bit grayscale data, (A) shows a case where adjacent pixels of level 128 and level 127 in which the grayscale changes greatly are observed. When observing the vertical dotted line V1 shown in the figure, the line of sight does not move. Within one field period,
There is no movement of the pixel you are looking at. In other words, there is no lateral change. Therefore, the level 128 given to the vertical dotted line V1
The gradation of can be observed correctly. Similarly level 1
Even in the case of 27 vertical dotted lines V2, the gradation can be correctly observed.

However, if the eyes move within one field, for example, the diagonal dotted line S1 is B7 + B0 = level 1
It will be observed as 29. Also, another diagonal dotted line S2
Then it will be observed as a level of 255. Correctly, these points S1 and S2 are gradation display of 127 levels. As shown in the figure, the phenomenon that gradation is not displayed correctly is called pseudo contour. This is called a moving image pseudo contour because the gradation cannot be seen correctly due to the movement of the eyes or the overlapping of the gradation display of each subfield becomes incorrect when the image moves on the screen. In the pseudo contour generation amount shown in the figure, the horizontal direction corresponds to the distance in pixels or the number of pixels, the vertical direction is the time direction, and this inclination is the eye movement speed. Alternatively, this inclination is the moving speed of the image.

The time compression method shown in (B) is adopted as a method for suppressing the above-described pseudo contour of a moving image. As shown in the figure, by compressing the subfield and pushing it in the field, the pseudo contour generation amount is reduced as compared with the case shown in FIG. The time compression rate is T
f '/ Tf. However, in the gradation display method using the conventional subfield method, the sustain period Tsus that contributes to the light emission is about 15 μsec in the subfield corresponding to the least significant bit B0. The time length of Tsus corresponding to the above becomes short, and it becomes difficult to control light emission. If the number of bits is increased to increase the number of gradations,
Since the Tsus becomes shorter and shorter, it is difficult to suppress the moving image pseudo contour.

FIG. 7A is a schematic diagram showing the pseudo contour generation amount when the subfield method according to the present invention is adopted, which is shown in comparison with the conventional method shown in FIG. 6A. There is. In the present invention, the periods of the subfields corresponding to the bits B7 to B0 are all uniform time widths.
Looking at the pseudo contour generation amount, unless the time compression method is used,
Basically, it is not superior to the conventional method shown in FIG.

On the other hand, when the time compression is applied as shown in FIG. 6B, the pseudo contour generation amount is smaller than that in FIG. 6B. For example, Tsus is a subfield period (1.
615 msec), the compression ratio is 1.615.
It can be set to x8 / 16.7 = 0.77. Here, if the compression rate is increased too much, the ratio of the sustain period decreases and the luminous efficiency deteriorates. In this example, since the compression rate is 77%, the pseudo contour generation amount at this time can be reduced to 77%.

[0032]

As described above, according to the present invention, in the plasma display device which performs multi-gradation display by the subfield method, the pulse interval of the drive signal is adjusted in each subfield so that the number of pulses is large. The pulse interval is made short in the field, and the pulse interval is made long in the subfield where the number of pulses is small. As a result, it is possible to secure a sufficient sustain period even in the subfield corresponding to the least significant bit of multi-grayscale data, and it is possible to display grayscale in a stable manner. Further, since the sustain period of the subfield corresponding to the least significant bit can be sufficiently secured, the time compression rate can be made higher than in the conventional case, and the pseudo contour of the moving image can be suppressed. As a result, it is possible to display a high quality image. In particular, the driving method according to the present invention is a cost-effective method because it can be realized without significantly improving the conventional driving circuit by the subfield method.

[Brief description of drawings]

FIG. 1 is an exploded perspective view showing a configuration of a plasma display device according to the present invention.

FIG. 2 is a schematic diagram showing an electrode configuration of a plasma display device according to the present invention.

FIG. 3 is a timing chart showing a basic driving method of the plasma display device.

FIG. 4 is a timing chart showing a reference example of a subfield method.

FIG. 5 is a timing chart showing a subfield method according to the present invention.

FIG. 6 is a schematic diagram showing a mechanism of generating a moving image pseudo contour.

FIG. 7 is a schematic diagram showing a mechanism of generating a moving image pseudo contour.

[Explanation of symbols]

10 ... Front panel, 11 ... Glass substrate, 1
4 ... Dielectric layer, 15 ... Protective film, 20 ... Rear panel, 21 ... Glass substrate, 23 ... Dielectric material layer, 24 ... Partition wall, 25 ... Phosphor layer , H ... Data electrode, X ... Sustain electrode, Y ... Scan electrode

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[Procedure amendment]

[Submission date] September 13, 2001 (2001.9.1)
3)

[Procedure Amendment 1]

[Document name to be amended] Statement

[Correction target item name] Full text

[Correction method] Change

[Correction content]

[Document name] Statement

Patent application title: Plasma display device and driving method thereof

[Claims]

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a plasma display device and a driving method thereof. More specifically, it relates to an improved technique of the subfield method for the purpose of gradation display.

[0002]

2. Description of the Related Art Various flat panel type display devices have been developed as an image display device which replaces the currently mainstream cathode ray tube (CRT). As a flat panel type display device, a liquid crystal display device (LCD), an electroluminescence display device (ELD), and a plasma display device (PDP) are known. Among them, the plasma display device has advantages such as relatively large screen and wide viewing angle, excellent resistance to environmental factors such as temperature, magnetism and vibration, and long life. , Is expected to be applied to large-scale information terminal devices for public use as well as wall-mounted TVs for home use.

In a plasma display device, a voltage is applied to a discharge cell in which a discharge gas such as an inert gas is sealed in a discharge space, and vacuum ultraviolet rays generated by glow discharge in the discharge gas cause fluorescence in the discharge cell. It is a display device that emits light by exciting a body layer. That is, each discharge cell is driven by a principle similar to that of a fluorescent lamp, and a large number of discharge cells are collected as pixels to form one display screen. Basically, each discharge cell is driven on / off between lighting and extinguishing, and in principle, two-gradation display is performed. Plasma display devices are roughly classified into a DC drive type (DC type) and an AC drive type (AC type) according to a method of applying a voltage to a discharge cell. The AC type plasma display device is suitable for high definition because it is sufficient to form the barrier ribs that partition the individual discharge cells in the display screen in stripes. Further, since the surface of the electrode for discharging is covered with the dielectric layer, the electrode has advantages that it is hard to wear and has a long life.

[0004]

Basically, a subfield method is known in order to realize multi-gradation display in a plasma display device in which individual discharge cells are turned on / off to display a screen. . According to this method, one field is divided into a plurality of sub-fields corresponding to a plurality of bits because the weighted multi-tone data consisting of a plurality of bits is written and held in a pixel. Then, each bit is written in the corresponding subfield and a drive signal corresponding to the weighting of the bit is applied to the discharge cell to hold the bit. In other words, in this sub-field method, the display period of one field is divided into N sub-fields so that the display period is divided into N sub-fields in order to emit light the number of times corresponding to the weighting of each bit digit of N-bit pixel data. . For example, when the pixel data is 8 bits, the display period of one field is divided into eight subfields. At this time, the number of discharge light emission in each subfield is set to, for example, 1 time, 2 times, 4 times, 8 times, 16 times ... 128 times in order, and 256 gradations are obtained by combining these 8 subfields. Is displayed.

The number of times of discharge light emission corresponds to the number of pulses included in the drive signal. Conventionally, the pulse frequency of the drive signal applied to each subfield has been constant. In other words, the time intervals of the pulses are constant. Therefore, the subfield corresponding to the upper bits has a large number of times of light emission, and thus the subfield period is inevitably long. In contrast,
Since the number of times of light emission is small in the subfield corresponding to the lower bit, the time width of the subfield is small. In this way, conventionally, the emission width is modulated by adjusting the time width of each subfield. In this method, all subfields are set to fit within one field in order to maintain the brightness of the screen. By doing so, the time width of the subfield becomes smaller as the bit becomes lower. Particularly, in the least significant bit, the effective time width included in the subfield period becomes extremely short, and there is a problem that it is difficult to perform stable display.

Further, the subfield method has a problem that when a moving image is displayed on a television screen, the contour of the picture pattern is disturbed and a pseudo contour other than the actual contour appears, thereby disturbing the image quality. In this specification, a pseudo contour that appears when a moving image is displayed is called a moving image pseudo contour. Conventionally, a method called a time compression method has been used in order to suppress a moving image pseudo contour. This time compression method is a method of shortening the time width of each subfield and compressing and assigning all the subfields to a part of the time width of one field. For example, it is desirable to shorten the total time of the sub-fields and suppress it to about 1/2 or 1/3 in one field. However, if the pulse frequency of the drive signal is uniformly increased to shorten the subfield, the least significant bit (LS
The subfield time corresponding to B) becomes shorter,
If the above-mentioned time width is set to 1/2 or 1/3, the stability of discharge will be disturbed.

[0007]

SUMMARY OF THE INVENTION It is an object of the present invention to solve the problems of the subfield method described above and to provide a high quality plasma display device which has high brightness and is capable of suppressing moving picture pseudo contours. . The following measures have been taken to achieve this purpose. That is, a dischargeable gas is sealed between a pair of substrates joined to each other, one substrate is provided with first and second electrodes corresponding to each scanning line, and the other substrate is provided with the electrodes. Is a panel in which a third electrode is formed corresponding to each data line, and drives the first, second and third electrodes to sequentially write data in the intersections of each scanning line and each data line. And hold it,
In a plasma display device including a drive unit for displaying an image for one field, the drive unit writes and holds multi-gradation data consisting of a plurality of weighted bits,
One field is divided into a plurality of subfields corresponding to a plurality of bits, each bit is written in a corresponding subfield, and a driving signal having a pulse number corresponding to the weighting of the bit is applied to the first and second electrodes. Hold the relevant bit, and further adjust the pulse interval of the drive signal in each subfield to shorten the pulse interval in the subfield with a large number of pulses and lengthen the pulse interval in the subfield with a small number of pulses. Characterize. Preferably, the driving unit adjusts a pulse interval of the driving signal in each subfield, and thus allocates a uniform time width to each subfield in one field. Further, the drive unit may compress and adjust the pulse interval of the drive signal in each subfield, and thus compress and allocate all the subfields to a part of the time width of one field.

According to the present invention, the pulse frequency (pulse interval) is variably set in each subfield, instead of making the pulse frequency of the drive signal constant in each subfield as in the conventional case. Specifically, the pulse interval is shortened in the subfield corresponding to the upper bits of the multi-gradation data, while the pulse interval is lengthened in the subfield corresponding to the lower bits. By doing so, it is possible to equalize the time widths assigned to the subfields within one field, and it is possible to secure sufficient time even for the subfields corresponding to LSB. Thereby, the discharge can be stabilized. Further, since a sufficient time width can be secured even in the LSB side subfield, it is possible to apply time compression to 1/2 or 1/3 over all the subfields, and it is possible to suppress a moving image pseudo contour.

[0009]

BEST MODE FOR CARRYING OUT THE INVENTION Embodiments of the present invention will be described in detail below with reference to the drawings. FIG. 1 is a schematic exploded perspective view showing the basic configuration of a plasma display device according to the present invention. This plasma display device is an AC type and belongs to a so-called three-electrode type. As shown in the figure, the present plasma display device comprises a front panel 10 and a rear panel 20 joined together at their outer peripheral portions. The light emission of the phosphor layer 25 on the rear panel 20 is observed through the front panel 10.

The front panel 10 is provided with a transparent glass substrate 11 and stripes on the glass substrate 11.
A plurality of pairs of scan electrodes Y and sustain electrodes X made of a transparent conductive material, and a dielectric layer 14 made of a dielectric material formed on the glass substrate 11 so as to cover these electrodes.
And a protective film 15 made of MgO or the like formed on the dielectric layer 14. A bus electrode made of a metal material having a low electric resistivity is formed on the scan electrode Y made of a transparent conductive material in order to reduce its impedance. Similarly, a bus electrode made of a narrow metal material is formed on the sustain electrode X made of a transparent conductive material. The gap size between the scan electrode Y and the sustain electrode X is 10 to 100 μm. The array pitch of the pair of scan electrodes Y and sustain electrodes X is 600 to 1200 μm.

On the other hand, the rear panel 20 has a glass substrate 21.
A plurality of data electrodes H arranged in stripes on the dielectric material layer 23 formed on the glass substrate 21 including the data electrodes H, and the adjacent data electrodes H on the dielectric material layer 23. Insulating barrier ribs 24 extending in parallel with the data electrodes H in a region between the barrier ribs and the barrier ribs 24 from above the dielectric material layer 23.
And a phosphor layer 25 provided over the side wall surface of the. The phosphor layer 25 is a red phosphor layer 25R when performing color display in an AC plasma display device.
It is composed of a green phosphor layer 25G and a blue phosphor layer 25B, and the phosphor layers 25R, 25G, 2 of the respective colors are formed.
5B are provided in a predetermined order. FIG. 1 is an exploded perspective view, and the top of the partition wall 24 on the rear panel 20 side actually contacts the protective film 15 on the front panel 10 side. A pair of scan electrodes Y and sustain electrodes X and two partitions 24
The region where the data electrode H located between the two overlaps corresponds to the discharge cell. A discharge gas, such as an ionizable rare gas, is enclosed in the discharge space surrounded by the adjacent partition walls 24, the phosphor layer 25, and the protective film 15. The front panel 10 and the rear panel 20 are joined at their outer peripheral portions using frit glass. The height of the partition wall 24 is 50 to 200 μm.
Further, the width dimension of the groove sandwiched between the adjacent partition walls 24 is 100 to
It is 400 μm.

The row direction in which the projected images of the scan electrodes Y and the sustain electrodes X extend and the column direction in which the projected images of the data electrodes H extend are orthogonal to each other, and the pair of scan electrodes Y and sustain electrodes X emit light of the three primary colors. A region orthogonal to one set of the phosphor layers 25R, 25G, 25B corresponds to one pixel. Since a glow discharge is generated between the pair of scan electrodes Y and sustain electrodes X, this type of AC plasma display device is called "surface discharge type".

This surface discharge type plasma display device has a three-electrode structure in which a dischargeable gas is sealed between a pair of substrates 11 and 21 bonded to each other as described above, and electrodes are formed on each substrate. Has become. That is, the first and second substrates 11 corresponding to the scanning lines extending in the row direction are formed on one substrate 11.
The scan electrodes Y and the sustain electrodes X, which are the electrodes, are formed, and the data electrodes H, which are the third electrodes, are formed on the other substrate 21 corresponding to the data lines extending in the column direction. Dots are formed at the intersections of each scanning line and each data line, and three dots of RGB form one pixel.

[0014]

FIG. 2 schematically shows a three-electrode structure of the plasma display device shown in FIG. The n scanning electrodes Y1 to Yn are formed corresponding to the scanning lines along the row direction (horizontal direction). Here, n represents the number of scanning lines. The sustain electrodes X1 to Xn are formed in parallel with the scan electrodes Y1 to Yn. On the other hand, m data electrodes H1 to Hm are formed along the data lines in the column direction (vertical direction). Here, m represents the number of data lines. A dot D is formed at each intersection of the m data lines and the n scan lines. A plasma discharge is excited by applying a drive signal to the scan electrode Y, the sustain electrode X, and the data electrode H in accordance with a predetermined sequence, and the ultraviolet rays generated thereby are irradiated to the phosphor to emit light, thereby displaying an image. It will be possible.

FIG. 3 is a timing chart schematically showing a driving method of the three-electrode type plasma display device shown in FIG. This timing chart shows a drive waveform focusing on the dot D located in the i-th column and the j-th row.
A drive circuit (not shown) connected to the panel shown in FIG.
Applies the first drive signal to the scan electrode Yj,
The second drive signal is applied to j and the third drive signal is applied to the data electrode Hi. In the example of FIG. 3, one field period Tf
This is a case where two-gradation display is performed using all of the above.

The field period Tf is a reset period Tr,
It is divided into an address period Ta and a holding period Tsus. First, in the reset period Tr, before writing data to each dot, the charge inside the panel is discharged to reset the entire screen to a uniform state. Alternatively, it may be reset to a uniform state by charging the charges inside the panel. For this purpose, a drive signal is applied between all scan electrodes Y and sustain electrodes X in the reset period Tr. The scan electrodes Y are electrically separated one by one, while the sustain electrodes X are all commonly connected. Subsequently, in the address period Ta, all scanning lines are line-sequentially scanned to select one line at a time. In order to select the j-th scanning line, the pulse-shaped first drive signal is applied to the scanning electrode Yj. The period during which one scan line is selected is set to Tsel
And is equal to the pulse width of the first drive signal. At this time, the third drive signal is sent to the data electrode H side in synchronization with the line-sequential scanning of the scan lines. For example, when writing 1 data to the dot in the j-th row and the i-th column, the illustrated third drive signal is applied as a pulse to the data electrode Hi. Conversely, no pulse is applied when writing 0 data to the dot in the j-th row and the i-th column. In this way, the address period Ta is a period for addressing and selecting the scanning lines, and the selection is repeated for the number of scanning lines of the display, and in accordance therewith, the third drive signal corresponding to the binary information 0 and 1 of the image is generated. It is applied to the data electrode H. The address period Ta = Tsel × n. Corresponding to the dot Dji to be displayed, ON to the data electrode Hi
= 1 or OFF = 0 drive signal is applied to scan electrode Yj
As for, the first drive signal is applied according to the position of the dot Dji. After the line-sequential scanning for one screen is completed in the vertical direction (vertical direction), the holding period (sustain period) Tsu
Enter s.

In the sustain period Tsus, the light emitting / non-light emitting operation is performed according to the ON / OFF state written in the address period Ta. ON = 1 in the address period Ta
When is written, light emission is maintained to obtain a desired brightness. On the contrary, when OFF = 0 is written in the address period, the non-light emitting state is maintained. In addition, the sustain period Tsu
At s, a pulsed drive signal is applied between the scan electrode Y and the sustain electrode X, and light emission is repeated according to the pulse. As described above, the plasma display device basically turns dots on and off.
It is driven and two-gradation display is performed.

Next, with reference to FIG. 4, a driving method for performing multi-gradation display in the plasma display device will be described. Figure 4
Before describing the driving method of the present invention, shows a multi-gradation display by a conventional general subfield method as a reference. In the case of a two-gradation display, the data written in each dot has a 1-bit structure of 01. On the other hand, in the case of multi-gradation display, multi-bit data consisting of a plurality of bits weighted in order from the upper digit to the lower digit is written in each dot. In the subfield method, one field period Tf is divided into a plurality of subfields corresponding to a plurality of bits. In the illustrated example, the multi-gradation data is 8 gradation data from the most significant bit B7 to the least significant bit B0, and the field period Tf is divided into eight subfield periods T7, T6, T5, ... T0. ing.
Here, each bit is written in the corresponding subfield, and a drive signal having a pulse number corresponding to the weighting of the bit is applied between the scan electrode and the sustain electrode during the holding period to hold the bit. In the illustrated example, the most significant bit B7
Is written and maintained in the subfield period T7, the next bit B6 is written in the next subfield period T6,
The least significant bit B0 is sequentially written in the field period Tf.

In each subfield, the drive sequence shown in FIG. 3 is performed to write the corresponding bit. For example, focusing on the first subfield T7,
The screen is collectively reset in the reset period Tr, the most significant bit B7 is written in the address period Ta, and the bit data B7 written in the sustain period Tsus is maintained. B
The dot in which 7 = 1 is written repeats pulse emission, and the dot in which B7 = 0 is written remains non-emissive. Similarly, the subfield driving sequence is repeated in each period T6, T5, ..., T0. In each subfield period T, a period Tr + that does not contribute to the actual brightness
The time length of Ta is the same, but the effective period Tsus that contributes to the brightness is different. That is, drive signals of the number of pulses according to the weighting of bits are applied to each subfield. The most significant bit is applied with the largest number of pulses, the next bit B6 is applied with half the number of pulses, and the number of pulses is halved in the following order. Conventionally, a drive signal having a constant pulse frequency in all subfield periods has been applied between the scan electrodes and the sustain electrodes. Therefore, the sustain period Tsus has a time length simply according to the weighting of the corresponding bit. Therefore, the subfield period T in which Tr, Ta, and Tsus are summed becomes shorter from the most significant bit to the least significant bit, such as T7 to T0.

In the example shown in FIG. 4, the actual field period Tf
On the other hand, if the gradation number is, for example, 256 gradations of 8 bits,
The drive sequence shown in FIG. 3 is repeated as a subfield eight times within the field period Tf, and light emission is performed during the weighted sustain period Tsus. The emission luminance per pulse is constant, but by extending the time length of the sustain period according to weighting in each subfield, the effect is visually integrated over one field period Tf, and the brightness gradation is obtained. Can be recognized as Such a method is called a subfield method.

The problem of the general subfield method shown in FIG. 4 will be briefly described. To simplify the explanation,
It is assumed that one subfield includes only the reset period Tr, the address period Ta, and the sustain period Tsus. The reset period Tr is common to all the subfields and is, for example, 0.4 msec. The address period Ta is also common to all subfields,
For example, it is 1.2 msec. This numerical value corresponds to the VGA standard, and when the number of scanning lines n = 480 and the selection period Tsel of one scanning line is 2.5 μsec, 2.5 μsec × 480 = 1.2 msec is given. Here, assuming that the multi-gradation data has an 8-bit structure, one field period Tf is divided into eight subfield periods T7 to T0. Here, according to the normal NTSC standard, one field period Tf is 16.6 msec. In this case, the sustain period Tsus of the subfield corresponding to the least significant bit is about 0.0149 msec. Therefore, the subfield period T0 corresponding to the least significant bit B0 is reset period 0.4 msec, address period 1.2 msec, and sustain period Tsus0.
The total of 0149 msec is 1.614 msec. When calculated in the same manner, the time length of the subfield period T1 corresponding to the bit B1 is 1.68 msec, and the subfield period T7 corresponding to the most significant bit B7 is 3.
It will be 56 msec. As described above, the weighting of each bit is performed by the length of the sustain period Tsus. In the subfield method, the number of subfields increases as the number of gradations increases. Further, increasing the number of scanning lines n means extending the address period Ta.
As a result, when the number of gradations is increased or the number of scanning lines is increased to improve the image quality, the ratio of the total period of each sustain period Tsus to the actual field period Tf is decreased, which deteriorates the brightness. This is an obstacle to high image quality.

FIG. 5 is a schematic timing chart showing the driving method of the plasma display device according to the present invention. In order to facilitate understanding, parts corresponding to those in FIG. 4 are designated by corresponding reference numerals. . The plasma display device basically has a display characteristic that the brightness changes according to the number of pulses applied during the sustain period. Focusing on this point, in the present invention, the brightness modulation is performed not by the time width modulation but by the number of pulses. The time width control according to the weighting of the sustain period Tsus is not necessarily required as in the conventional example shown in FIG. 4, and each subfield period T7, T6, ..., T0 is set as shown in the timing chart of FIG. The sustain period T that is constant and directly contributes to the luminance in the sustain period T
The period of sus is the same, but each sustain period Ts
The number of pulses corresponding to the weighting of bits is assigned to us. In other words, the pulse frequency is variable in each subfield.

In the example of FIG. 5, assuming that the sustain period Tsus is equally spaced in the field period Tf, the time length of Tsus is B5 as compared with the case of the time width control shown in FIG.
Corresponds to the length of time allocated to. On the other hand, each Ts
The number of pulses applied to us corresponds to the weighting of gradation, and assuming that the pulse frequency of the least significant bit B0 is f1, the frequency at B1 is f2 = 2 × f1, and at B4 f4 = 4 × f1, F128 for upper bit B7
It is sufficient to apply a drive signal having a pulse frequency of = 128 × f1. However, this is a case where the number of pulses per unit time and the luminance are linear to each other, but this is not a problem because it may be non-linear as long as it matches the light emission characteristics. In this new method, the least significant bit LSB
Even in the subfield corresponding to, the sustain period Tsu
Since the length of s is equivalent to the case of the upper bits, it is possible to adopt the time compression method and squeeze the total period of subfields into a part of one field period. Even if the time compression method is used, the sustain period Ts corresponding to the least significant bit
Since the us can be sufficiently secured, it is possible to eliminate the instability of the display operation.

As described above, according to the present invention, the driving unit of the plasma display device adjusts the pulse interval of the drive signal in each subfield to shorten the pulse interval in the subfield in which the number of pulses is large and to decrease the number of pulses. The pulse interval is set longer in the subfield. For example, the driving circuit of the plasma display panel adjusts the pulse interval of the driving signal in each subfield so that an equal time width is assigned to each subfield in one field. In addition, the drive circuit
It is also possible to compress and adjust the pulse interval of the drive signal in each sub-field and thereby compress all the sub-fields in a part of the time width of one field to suppress the allocation moving image pseudo contour.

Here, a mechanism of generating a moving image pseudo contour in the plasma display device will be briefly described. The pseudo contour of the moving image is generated in principle when the sub-field method is adopted for displaying the gradation, and the emission of the weighted time width of each bit is dispersed in the field. to cause. When observing a pixel with a certain gradation, if the pixel remains in the eyes of the observer within one field period, the correct luminance signal corresponding to the gradation data is perceived by the visual integration function. can do. However, when observing the video, the line of sight moves,
If the gradation of the image you are looking at differs from the gradation after moving, the correct subfield emission that constitutes the gradation will not come into your eyes, and the incorrect subfield emission will enter, resulting in a floor failure. It is perceived as light different from the key data. This phenomenon is called moving image pseudo contour. Even if the line of sight does not move, when the signal is switched in the field and reflected in the signal of the subfield, a pseudo contour appears again.

With reference to FIG. 6, the lengths of fields and subfields and the appearance of pseudo contours will be specifically described. As an example, in the case of 8-bit grayscale data, (A) shows a case where adjacent pixels of level 128 and level 127 in which the grayscale changes greatly are observed. When observing the vertical dotted line V1 shown in the figure, the line of sight does not move. Within one field period,
There is no movement of the pixel being viewed. In other words, there is no lateral change. Therefore, the level 128 given to the vertical dotted line V1
The gradation of can be observed correctly. Similarly level 1
Even in the case of 27 vertical dotted lines V2, the gradation can be correctly observed.

However, if the eyes move within one field, for example, the diagonal dotted line S1 is B7 + B0 = level 1
It will be observed as 29. Also, another diagonal dotted line S2
Then it will be observed as a level of 255. Correctly, these points S1 and S2 are gradation display of 127 levels. As shown in the figure, the phenomenon that gradation is not displayed correctly is called pseudo contour. This is called a moving image pseudo contour because the gradation cannot be seen correctly due to the movement of the eyes or the overlapping of the gradation display of each subfield becomes incorrect when the image moves on the screen. In the pseudo contour generation amount shown in the figure, the horizontal direction corresponds to the distance in pixels or the number of pixels, the vertical direction is the time direction, and this inclination is the eye movement speed. Alternatively, this inclination is the moving speed of the image.

The time compression method shown in (B) is adopted as a method for suppressing the above-described pseudo contour of a moving image. As shown in the figure, by compressing the subfield and pushing it in the field, the pseudo contour generation amount is reduced as compared with the case shown in FIG. The time compression rate is T
f '/ Tf. However, in the gradation display method using the conventional subfield method, the sustain period Tsus that contributes to the light emission is about 15 μsec in the subfield corresponding to the least significant bit B0. The time length of Tsus corresponding to the above becomes short, and it becomes difficult to control light emission. If the number of bits is increased to increase the number of gradations,
Since the Tsus becomes shorter and shorter, it is difficult to suppress the moving image pseudo contour.

FIG. 7A is a schematic diagram showing the pseudo contour generation amount when the subfield method according to the present invention is adopted, which is shown in comparison with the conventional method shown in FIG. 6A. There is. In the present invention, the periods of the subfields corresponding to the bits B7 to B0 are all uniform time widths.
Looking at the pseudo contour generation amount, unless the time compression method is used,
Basically, it is not superior to the conventional method shown in FIG.

On the other hand, when the time compression is applied as shown in FIG. 6B, the pseudo contour generation amount is smaller than that in FIG. 6B. For example, Tsus is a subfield period (1.
615 msec), the compression ratio is 1.615.
It can be set to x8 / 16.7 = 0.77. Here, if the compression rate is increased too much, the ratio of the sustain period decreases and the luminous efficiency deteriorates. In this example, since the compression rate is 77%, the pseudo contour generation amount at this time can be reduced to 77%.

[0032]

As described above, according to the present invention, in the plasma display device which performs multi-gradation display by the subfield method, the pulse interval of the drive signal is adjusted in each subfield so that the number of pulses is large. The pulse interval is made short in the field, and the pulse interval is made long in the subfield where the number of pulses is small. As a result, it is possible to secure a sufficient sustain period even in the subfield corresponding to the least significant bit of multi-grayscale data, and it is possible to display grayscale in a stable manner. Further, since the sustain period of the subfield corresponding to the least significant bit can be sufficiently secured, the time compression rate can be made higher than in the conventional case, and the pseudo contour of the moving image can be suppressed. As a result, it is possible to display a high quality image. In particular, the driving method according to the present invention is a cost-effective method because it can be realized without significantly improving the conventional driving circuit by the subfield method.

[Brief description of drawings]

FIG. 1 is an exploded perspective view showing a configuration of a plasma display device according to the present invention.

FIG. 2 is a schematic diagram showing an electrode configuration of a plasma display device according to the present invention.

FIG. 3 is a timing chart showing a basic driving method of the plasma display device.

FIG. 4 is a timing chart showing a reference example of a subfield method.

FIG. 5 is a timing chart showing a subfield method according to the present invention.

FIG. 6 is a schematic diagram showing a mechanism of generating a moving image pseudo contour.

FIG. 7 is a schematic diagram showing a mechanism of generating a moving image pseudo contour.

[Explanation of Codes] 10 ... Front Panel, 11 ... Glass Substrate, 1
4 ... Dielectric layer, 15 ... Protective film, 20 ... Rear panel, 21 ... Glass substrate, 23 ... Dielectric material layer, 24 ... Partition wall, 25 ... Phosphor layer , H ... Data electrode, X ... Sustain electrode, Y ... Scan electrode

─────────────────────────────────────────────────── ─── Continuation of the front page (51) Int.Cl. ⁷ Identification code FI theme code (reference) H04N 5/66 101 G09G 3/28 K F term (reference) 5C058 AA11 BA05 BA07 BA35 BB25 5C080 AA05 BB05 DD01 DD30 EE19 EE29 FF12 JJ01 JJ04 JJ06

Claims (4)

[Claims] 1. A dischargeable gas is sealed between a pair of substrates joined to each other, and one substrate has first and second electrodes formed corresponding to each scanning line, and the other. A panel in which a third electrode is formed corresponding to each data line on the substrate, and a portion where each scan line intersects each data line are sequentially driven by driving the first, second and third electrodes. In a plasma display device including a driving unit that writes and holds data and displays an image of one field, the driving unit writes and holds multi-gradation data consisting of a plurality of weighted bits, and therefore, a plurality of bits. One field is divided into a plurality of sub-fields corresponding to the above, each bit is written in the corresponding sub-field, and the drive signal having the number of pulses corresponding to the weighting of the bit is first
And the bit is applied to the second electrode to hold the bit, and the pulse interval of the drive signal is adjusted in each subfield to shorten the pulse interval in the subfield having a large number of pulses and to reduce the pulse interval in the subfield having a small number of pulses. A plasma display device having a long pulse interval. 2. The plasma according to claim 1, wherein the driving unit adjusts a pulse interval of the driving signal in each subfield, and thereby allocates a uniform time width to each subfield in one field. Display device. 3. The driving unit compresses and adjusts the pulse interval of the driving signal in each subfield, and compresses and allocates all the subfields to a part of the time width of one field. The plasma display device according to claim 1. 4. A dischargeable gas is sealed between a pair of substrates bonded to each other, and one substrate has first and second electrodes formed corresponding to each scanning line, and the other. For the panel in which the third electrode is formed on the substrate corresponding to each data line, the first electrode, the second electrode, and the third electrode are driven to form a portion at the intersection of each scan line and each data line. In the driving method of the plasma display device, which sequentially writes and holds data to display an image for one field, in order to write and hold multi-gradation data consisting of a plurality of weighted bits, one field corresponding to a plurality of bits Is divided into a plurality of sub-fields, each bit is written in the corresponding sub-field, and the drive signal having the number of pulses corresponding to the weighting of the bit is first divided.
And the bit is applied to the second electrode to hold the bit, and the pulse interval of the drive signal is adjusted in each subfield to shorten the pulse interval in the subfield having a large number of pulses and to reduce the pulse interval in the subfield having a small number of pulses. 2. A method of driving a plasma display device, characterized in that the pulse interval is lengthened.